JPWO2011099289A1 - Radio relay apparatus and radio relay method - Google Patents

Abstract

To provide a wireless relay device or a wireless relay method capable of improving resource utilization efficiency. In the radio relay apparatus for relaying a signal between the base station and the mobile station of the present invention, when the transmission unit transmits the SRS in the subframe immediately before the backhaul subframe, the SRS setting unit is , The final symbol of the access link subframe is set as an empty symbol in which no SRS is transmitted from the mobile station to the mobile station, and the reception unit receives a symbol one symbol before the empty symbol from the mobile station. After receiving the signal for the own device, the switching unit switches to transmission from the own device to the base station, and the transmitting unit transmits the SRS in the backhaul subframe immediately before the backhaul subframe. Otherwise, after the receiving unit receives a signal for the own device from the mobile station with the final symbol of the access link subframe, the switching unit Switches to transmission from the own apparatus to the base station.

Description

  The present invention relates to a wireless relay device and a wireless relay method.

  2. Description of the Related Art In recent years, in cellular mobile communication systems, it is becoming common to transmit not only audio data but also large-capacity data such as still image data and moving image data as information becomes multimedia. In order to realize the transmission of large-capacity data, active research has been conducted on techniques for realizing a high transmission rate using a high-frequency radio band.

  However, when a high-frequency radio band is used, a high transmission rate can be expected at a short distance, but attenuation due to a transmission distance increases as the distance increases. Therefore, when a mobile communication system using a high-frequency radio band is actually operated, a coverage area of a radio communication base station apparatus (hereinafter abbreviated as a base station) is reduced, and therefore, more base stations Need to be installed. Since installation of a base station requires a corresponding cost, there is a strong demand for a technique for realizing a communication service using a high-frequency radio band while suppressing an increase in the number of base stations.

  In response to such a request, in order to expand the coverage area of each base station, as shown in the radio relay system of FIG. 11, a base station 10 and a radio communication mobile station apparatus 20 (hereinafter abbreviated as a mobile station) A wireless transmission relay station device 30 (hereinafter, abbreviated as a relay station) is installed between the base station 10 and the mobile station 20, and a relay transmission technique for performing communication between the base station 10 and the mobile station 20 via the relay station 30 is being studied. . When the relay technology is used, a terminal that cannot communicate directly with the base station 10 and the base station 10 can communicate with each other via the relay station 30. The mobile station 40 is a mobile station connected to the base station 10.

[Description of TD relay]
Next, TD relay will be described with reference to FIGS. 12 is a conceptual diagram for explaining TD relay on the uplink, and FIG. 13 is a conceptual diagram for explaining TD relay on the downlink.

  In the uplink shown in FIG. 12, in subframe # 2 (Subframe # 2), mobile station 20 transmits to relay station 30 via an access link (Access link), and in subframe # 3 (Subframe # 3). The relay station 30 communicates with the base station 10 through a backhaul link. Then, in subframe # 4, the mobile station 20 performs transmission to the relay station 30 again. Similarly, in the downlink shown in FIG. 13, in subframe # 2 (Subframe # 2), relay station 30 transmits mobile station 20 through an access link (Access link), and subframe # 3 (Subframe # 3). ), The base station 10 communicates with the relay station 30 through a backhaul link. And in sub-frame # 4, the relay station 30 transmits the mobile station 20 again.

  As described above, in TD relay, transmission from the base station 10 to the relay station 30 and transmission from the relay station 30 to the mobile station 20 are divided by time. Thus, by dividing the communication on the backhaul link and the communication on the access link on the time axis, the time for transmission by the relay station 30 and the time for reception can be divided. Therefore, the relay station 30 can relay the signal without being affected by the sneak current between the transmission antenna and the reception antenna.

[Explanation of guard time]
However, in order to switch from transmission to reception or from reception to transmission in the relay station 30, it is necessary to provide a guard period in order to switch an RF (Radio Frequency) circuit. FIG. 14 is a diagram for explaining a guard period. In the relay station 30, as shown in FIG. 14, each guard period is provided in a subframe when switching from transmission to reception or switching from reception to transmission. The guard period is assumed to be approximately 20 [μs] depending on the performance of the device.

[Switching timing]
In TD relay, a guard period is required, so that a subframe that cannot be transmitted or received occurs. In the 3GPP RAN1 # 59b meeting, in order to provide a guard period, a method of sacrificing the first OFDM symbol of the backhaul subframe (hereinafter referred to as Case A), a method of sacrificing the final OFDM symbol of the backhaul subframe (hereinafter referred to as “Case A”) , Case B), a method of sacrificing the last OFDM symbol of the access link (hereinafter referred to as Case C), and the like have been studied (see Non-Patent Document 1).

  Next, Case A, Case B, and Case C described above will be described with reference to FIGS. 15 is a diagram for explaining an example [1] in which a guard period is provided (corresponding to Case A), and FIG. 16 is a diagram for explaining an example [2] in which a guard period is provided (corresponding to Case B). FIG. 17 is a diagram (corresponding to Case C) for explaining an example [3] in which a guard period is provided. In the figure, the horizontal axis represents time (Time) [μs].

  15 to 17, subframe A (backhaul subframe) indicates communication from the relay station 30 to the base station 10, and subframes B and C (access link subframe) are transmitted from the mobile station 20 to the relay station. Communication to 30 is shown. Each subframe A, B, C includes SC-FDMA (Single Carrier-Frequency Multiple Access) symbols # 0 to # 13. Each symbol length of the SC-FDMA symbol is approximately 71.4 [ms].

  Also, in FIG. 15 to FIG. 17, the period between the arrows indicated by Δshift B or Δshift F is a guard period. In addition, the switching period in the figure is a time required for the relay station 30 to switch from transmission to reception or from reception to transmission.

  15 to 17, rUE transmission is the transmission timing of the mobile station 20 to the relay station 30, RN reception is the reception timing of the relay station 30 from the mobile station 20, and RN transmission is the relay station 30. ENB reception indicates the transmission timing of the base station 10 from the relay station 30.

  Also, in FIGS. 15 to 17, the blocks indicating SC-FDMA symbols # 0 to # 13 (# is omitted, and only the numbers are shown) are inclined, indicating a symbol propagation delay. For example, in FIG. 15, the symbol transmitted from the mobile station 20 to the relay station 30 at time T1 is received by the relay station 30 at time T2. Similarly in other FIGS. 16 and 17, the slope of the block indicates the propagation delay of the symbol.

  Here, the relay station 30 can control the reception timing from the mobile station 20 at the local station (or the transmission timing of the mobile station 20 connected to the local station to the local station). Note that the reception timing of the base station 10 from the relay station 30 (or the transmission timing of the relay station 30 to the base station 10) is set by the base station 10.

  In the example [1] (Case A) in which the guard period shown in FIG. 15 is provided, the relay station 30 transmits SC-FDMA symbols # 1 to # 13 (in the case of the normal CP length) to the base station 10. The relay station 30 can transmit SC-FDMA symbol # 13. The SC-FDMA symbol # 13 is an SRS (Sounding Reference Signal) transmission symbol (specified in the Rel. 8 LTE specification). That is, the relay station 30 can transmit SRS.

[Description of SRS]
SRS is a signal for measuring line quality in a wide band. When the mobile station transmits the SRS to the base station, the base station measures the channel quality of the RB to which the SRS is transmitted, and uses it as a reference for allocating resources to the mobile station. SRS is arranged in SC-FDMA symbol # 13. When transmitting SRS, the mobile station transmits PUCCH (Physical Uplink Control Channel) and PUSCH (Physical Uplink Shared Channel) using SC-FDMA symbols # 0 to # 12, and transmits SRS using SC-FDMA symbol # 13.

  In the example [2] (Case B) in which the guard period shown in FIG. 16 is provided, the relay station 30 transmits SC-FDMA symbols # 0 to # 12 (in the case of the normal CP length) to the base station 10. In the example shown in FIG. 8 LTE PUCCH and PDSCH formats can be applied to the backhaul line as they are. Also, R-PUCCH (relay PUCCH) and R-PUSCH (relay PUSCH) use SC-FDMA 0 to 12 when SC-FDMA 13 is used for SRS.

  In the example [3] (Case C) in which the guard period shown in FIG. 17 is provided, the relay station 30 transmits SC-FDMA symbols # 0 to # 13 (in the case of the normal CP length) to the base station 10. Although the relay station can transmit all SC-FDMA symbols, symbols that the relay station 30 can receive from the mobile station 20 connected to the relay station 30 are SC-FDMA symbols # 0 to # 12 (in the case of a normal CP). Become.

3GPP RAN1 59bis “R1-100807 WF on timing of backhaul and access link in uplink”

  Here, in order to realize the example [1] in which the guard period shown in FIG. 15 is provided, the relay station 30 shifts the UL reception timing of the access link backward by Δshift B behind the UL transmission timing of the backhaul. It ’s fine. However, in the example [1] (Case A) in which the guard period shown in FIG. 15 is provided, a new PUCCH format and PUSCH format that do not transmit SC-FDMA symbol # 0 are required. In particular, in PUCCH including ACK / NACK, CQI, and the like, when SC-FDMA symbol # 0 is simply punctured and transmitted, the orthogonality of codes used to multiplex PUCCH is lost. Therefore, there is a problem that a new format that does not break orthogonality is required.

  In order to realize the example [2] in which the guard period shown in FIG. 16 is provided, the relay station 30 shifts the UL reception timing of the access link forward by Δshift F ahead of the UL transmission timing of the backhaul (Backhaul). Just do it. However, in the example [2] (Case B) in which the guard period shown in FIG. 16 is provided, since the relay station cannot transmit the SRS with the SC-FDMA symbol # 13, the channel quality between the relay station and the base station is wide. It is difficult to measure in the band.

  In order to realize the example [3] in which the guard period shown in FIG. 17 is provided, the relay station 30 sets the UL reception timing of the access link to the UL transmission timing of the backhaul (Backhaul) in the same manner as the example shown in FIG. Shift backward by Δshift B. However, in the example [3] (Case C) in which the guard period shown in FIG. 17 is provided, the cell-specific SRS is always set in the access link in the subframe immediately before the backhaul subframe, and is connected to the relay station. The operation is such that the SRS is not assigned to the mobile station that is operating. Therefore, the mobile station connected to the relay station cannot transmit PUSCH, PUCCH, and SRS using SC-FDMA13.

  Also, in the example [3] (Case C) in which guard periods shown in FIG. 17 are provided, the arrangement of cell-specific SRSs is determined for each cell in a subframe in which SRS is transmitted, and the relay station moves from the cell. As the station-specific SRS arrangement, a transmission interval and a transmission subframe can be specified.

  However, in LTE, patterns that can be designated are determined in advance. Therefore, there is a possibility that the mobile station connected to the relay station may transmit the SRS in the subframe immediately before the backhaul subframe. At this time, the mobile station is transmitting SRS, but the relay station ignores the SRS of the mobile station and switches to transmission.

  An object of the present invention is to provide a wireless relay device or a wireless relay method that can improve resource utilization efficiency.

  The present invention is a radio relay apparatus for relaying a signal between a base station and a mobile station, and a backhaul subframe which is a subframe for performing communication between the base station and the own apparatus is provided. The backhaul subframe using a transmission unit that transmits a signal and an SRS toward the base station, and an access link subframe that is a subframe for performing communication between the mobile station and the own device. A reception unit for receiving the signal and SRS transmitted toward the own device at the reception start timing of the access link subframe shifted before the transmission end timing of the transmission, and transmission from the own device to the base station A switching unit that switches between a transmission mode and a reception mode in which reception from the mobile station is performed, and an SRS setting that sets the arrangement of SRSs that the mobile station transmits to its own device When the transmitting unit transmits the SRS in a subframe immediately before the backhaul subframe, the SRS setting unit is configured such that the mobile station receives the final symbol of the access link subframe. The SRS to be transmitted toward the own device is set as an empty symbol that is not arranged, and the reception unit receives a signal transmitted from the mobile station toward the own device with a symbol immediately before the empty symbol. Thereafter, the switching unit switches from the reception mode to the transmission mode, and when the transmission unit does not transmit the SRS in a subframe immediately before the backhaul subframe, the reception unit After receiving the signal transmitted from the mobile station to the mobile station in the final symbol of the subframe, the switching unit performs the reception mode. Switching to the transmission mode from provides wireless relay apparatus characterized by.

In addition, the present invention is a radio relay apparatus for relaying a signal between a base station and a mobile station, and is a backhaul subframe that is a subframe for performing communication between the base station and the own apparatus. The backhaul is transmitted using a transmission unit that transmits a signal and an SRS toward a base station using a frame, and an access link subframe that is a subframe for performing communication between the mobile station and the own apparatus. A reception unit that receives a signal and SRS transmitted to the own device at a reception start timing of the access link subframe shifted after a transmission end timing of the subframe, and a transmission from the own device to the base station. A switching unit that switches between a transmission mode to be performed and a reception mode to perform reception from the mobile station, and an SR that sets an arrangement of SRSs that the mobile station transmits toward the own device When the transmission unit transmits the signal using the first symbol of the backhaul subframe, the SRS setting unit is configured so that the mobile station transmits the final symbol of the access link subframe to the mobile station. After setting the SRS to be transmitted toward as an empty symbol that is not arranged, the receiving unit receives a signal transmitted from the mobile station toward the own device at a symbol preceding the empty symbol, The switching unit switches from the reception mode to the transmission mode, and when the transmission unit does not transmit the signal using the first symbol of the access link subframe, the reception unit uses the last symbol of the access link subframe. After receiving the signal transmitted from the mobile station to the own device, the switching unit starts the transmission from the reception mode. It switched to the mode,
A wireless relay device is provided.

  In addition, the present invention is a radio relay apparatus for relaying a signal between a base station and a mobile station, and is a backhaul subframe that is a subframe for performing communication between the base station and the own apparatus. The backhaul is transmitted using a transmission unit that transmits a signal and an SRS toward a base station using a frame, and an access link subframe that is a subframe for performing communication between the mobile station and the own apparatus. A reception unit that receives a signal and SRS transmitted to the own device at a reception start timing of the access link subframe shifted after a transmission end timing of the subframe, and a transmission from the own device to the base station. A switching unit that switches between a transmission mode to be performed and a reception mode to perform reception from the mobile station, and an SR that sets an arrangement of SRSs that the mobile station transmits toward the own device And when the transmitter transmits the signal with the final symbol of the backhaul subframe, after the transmitter transmits the signal with the final symbol of the backhaul subframe, The switching unit switches from the transmission mode to the reception mode, and when the transmission unit does not transmit the signal with the final symbol of the backhaul subframe, the SRS setting unit selects the final symbol of the backhaul subframe. , The SRS that is transmitted from the device to the base station is set as an empty symbol, and after the transmission unit transmits the signal with a symbol immediately before the final symbol, the switching unit The transmission unit switches from the transmission mode to the reception mode, and the reception unit switches the transmission unit from the transmission mode to the reception mode. And then receiving a signal transmitted from the mobile station to the mobile station with the final symbol of the access link subframe having the same subframe number as the backhaul subframe. Providing equipment.

  In the radio relay apparatus, the SRS setting unit determines a cell-specific SRS arrangement for each cell as a subframe in which the base station or the own apparatus may receive SRS, and determines the determined cell-specific The empty symbol is set by determining the SRS arrangement specific to the mobile station from the subframes included in the SRS arrangement.

  Further, the present invention is a radio relay method for relaying a signal between a base station and a mobile station, and a reception start timing of an access link subframe shifted before a transmission end timing of a backhaul subframe If the signal and SRS transmitted to the relay station are received and the SRS is transmitted in the subframe immediately before the backhaul subframe, the last symbol of the access link subframe is set as the mobile station. Is set as an empty symbol that does not place an SRS to be transmitted to the relay station, and after receiving a signal transmitted from the mobile station to the relay station at a symbol preceding the empty symbol, Switch to transmission from the relay station to the base station, and the SRS is transmitted in the subframe immediately before the backhaul subframe. If not, the mobile station receives a signal to be transmitted to the relay station in the last symbol of the access link subframe, and then switches to transmission from the relay station to the base station. A wireless relay method is provided.

  The present invention is also a radio relay method for relaying a signal between a base station and a mobile station, wherein the access link subframe reception start timing shifted after the backhaul subframe transmission end timing is provided. When the signal transmitted to the relay station and the SRS are received and a signal is transmitted using the first symbol of the backhaul subframe, the mobile station transmits the final symbol of the access link subframe to the relay station. An SRS to be transmitted is set as an empty symbol that is not arranged, and after receiving a signal transmitted from the mobile station to the relay station with a symbol preceding the empty symbol, the base station transmits the signal to the relay station. If the signal is not transmitted in the first symbol of the backhaul subframe, A radio relay method characterized by switching to transmission from the relay station to the base station after receiving a signal transmitted from the mobile station to the relay station in a final symbol of a sllink subframe. provide.

  The present invention is also a radio relay method for relaying a signal between a base station and a mobile station, wherein the access link subframe reception start timing shifted after the backhaul subframe transmission end timing is provided. When the signal and SRS transmitted to the relay station are received and the signal is transmitted with the final symbol of the backhaul subframe, after the signal is transmitted with the final symbol of the backhaul subframe, When the mobile station switches to reception from the relay station and the signal is not transmitted in the final symbol of the backhaul subframe, the relay station directs the final symbol of the backhaul subframe toward the base station. The SRS to be transmitted is set as an empty symbol that is not arranged, and the symbol preceding the last symbol is preceded by the preceding symbol After transmitting the signal, the mobile station switches to reception from the relay station, and from the mobile station to the relay station in the last symbol of the access link subframe having the same subframe number as the backhaul subframe. The wireless relay method is characterized by receiving the transmitted signal.

  According to the wireless relay device or the wireless relay method according to the present invention, resource utilization efficiency can be improved.

1 is a diagram illustrating a wireless relay system in a first embodiment The figure for demonstrating the timing which the relay station 100 switches transmission / reception The figure for demonstrating the transmission / reception switching operation | movement of the relay station 100 Block diagram showing the configuration of relay station 100 The figure for demonstrating the timing which the relay station 400 switches transmission / reception Block diagram showing the configuration of relay station 400 Block diagram showing the configuration of relay station 400A The figure for demonstrating the timing which the relay station 700 switches transmission / reception The figure for demonstrating the transmission / reception switching operation | movement of the relay station 700 Block diagram showing the configuration of relay station 700 Diagram showing wireless relay system Conceptual diagram for explaining TD relay on the uplink Conceptual diagram for explaining TD relay in downlink Illustration for explaining the guard period The figure for demonstrating the example [1] which provides a guard period The figure for demonstrating the example [2] which provides a guard period The figure for demonstrating the example [3] which provides a guard period

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

(Embodiment 1)
FIG. 1 is a diagram illustrating a wireless relay system according to the first embodiment. In the radio relay system shown in FIG. 1, as in FIG. 11, a radio communication relay station device 100 (hereinafter referred to as relay station 100) is provided between the base station 200 and the radio communication mobile station device 300 (hereinafter abbreviated as mobile station 300). And the communication between the base station 200 and the mobile station 300 is performed via the relay station 100. Thereby, a terminal (for example, the mobile station 300) that cannot directly communicate with the base station 200 can also communicate with the relay station 100. The mobile station 310 is a mobile station connected to the base station 200.

  In the wireless relay system shown in FIG. 1, time division relay (TD relay) is performed. As an example, two-hop relay from the base station 200 to the relay station 100 and from the relay station 100 to the mobile station 300 can be considered, but in this embodiment, two or more hops are also applicable.

[Description of SRS]
SRS is a signal for measuring line quality in a wide band. When the mobile station transmits the SRS to the base station, the base station measures the channel quality of the resource block (RB) in which the SRS is transmitted, and makes reference to allocate resources to the mobile station. SRS is arranged in SC-FDMA symbol # 13. When transmitting the SRS, the mobile station transmits the PUCCH and PUSCH using SC-FDMA symbols # 0 to # 12, and transmits the SRS to SC-FDMA symbol # 13.

  The SRS configuration includes cell-specific SRS configuration (Cell specific SRS subframe configuration) and UE-specific configuration (UE specific SRS configuration).

  First, as a subframe in which the base station (relay station in the relay station cell) may receive SRS, the cell-specific SRS arrangement is determined for each cell, and from the base station (from the relay station in the relay station cell) The mobile station is notified of cell-specific SRS arrangement by a higher layer control signal.

  Next, out of the subframes included in the determined cell-specific SRS configuration, the mobile station-specific SRS configuration (UE-specific SRS configuration) is determined, and the determined mobile station-specific SRS configuration information is as follows: SRS transmission interval information and transmission subframe offset information are reported from the base station (from the relay station in the relay station cell) to the mobile station.

  The mobile station transmits the SRS to the subframe assigned to the arrangement of the SRS unique to the mobile station, but the PUCCH and the SRS can be transmitted even if the SRS is not transmitted in the SRS transmittable subframe assigned to each cell. The PUSCH is transmitted using SC-FDMA symbols # 0 to # 12 and is not transmitted using SC-FDMA symbol # 13, thereby avoiding interference with the SRS.

  Here, as described above, in the example [2] (Case B) in which the guard period shown in FIG. 16 is provided, the relay station cannot transmit the SRS with the SC-FDMA symbol # 13. Therefore, it is conceivable to transmit the SRS to the subframe (SFN # N-1) immediately before the subframe allocated to the backhaul subframe (SFN # N).

  That is, since the relay station transmits SRS to the base station to SFN # N, SFN # (N−1) is set as a subframe for transmitting the SRS of the relay station in the cell of the base station. Further, since the relay station cannot receive the SC-FDMA symbol # 13 in the relay station cell, the relay station cell also assigns a subframe immediately before the subframe assigned to the backhaul subframe to be specific to the relay station cell. Set SRS. However, the SRS specific to the relay station cell is not assigned with the SRS specific to the mobile station, and is set so that the SC-FDMA symbol # 13 becomes empty.

  As described above, in the subframe immediately before all the backhaul subframes, it is necessary to set the cell-specific SRS arrangement in both the base station cell and the relay station cell. In a subframe in which cell-specific SRS arrangement is set, SC-FDMA symbol # 13 cannot be used for transmission of PUCCH and PUSCH. In particular, when the number of subframes used for the backhaul subframe is large, the probability that SC-FDMA symbol # 13 cannot be used for PUCCH and PUSCH increases, and resource utilization efficiency decreases.

  Therefore, in the radio relay system according to Embodiment 1, relay station 100 changes the switching timing from reception from mobile station 300 to its own station to transmission from its own station to base station 200 for each subframe. . Relay station 100 then determines whether or not SRS is assigned to the subframe immediately before the backhaul subframe as a reference for switching.

  Next, with reference to FIG. 2, a criterion for switching between transmission and reception by the relay station 100 will be described. FIG. 2 is a diagram for explaining the timing when the relay station 100 switches between transmission and reception.

  In FIG. 2, the period between the arrows indicated by Δshift F is a guard period. Further, the switching period in the figure is a time required for the relay station 100 to switch from reception to transmission or from reception to transmission.

  Also, in FIG. 2, rUE transmission is the transmission timing of the mobile station 300 connected to the relay station 100 to the relay station 100, RN reception is the reception timing of the relay station 100 from the mobile station 300, and RN transmission is The eNB reception indicates the transmission timing of the relay station 100 to the base station 200, and the reception timing from the relay station 100 at the base station 200.

  Also, in FIG. 2, the blocks indicating SC-FDMA symbols # 0 to # 13 (# is omitted in the figure and only the numbers are shown) are inclined, indicating a symbol propagation delay.

  Also, in FIG. 2, the blocks indicating SC-FDMA symbols # 0 to # 13 (# is omitted in the figure and only the numbers are shown) are inclined, indicating a symbol propagation delay. For example, in FIG. 2, the symbol transmitted from the mobile station 300 to the relay station 100 at time T4 is received by the relay station 100 at time T5.

  First, as the first transmission / reception switching timing (transmission / reception switching timing A in FIG. 2), the SC of the previous subframe of the backhaul subframe A1 for performing communication between the base station 200 and the own station. -When there is SRS transmission in FDMA symbol # 13, relay station 100 receives SC-FDMA symbol # 12 of access link subframe B1 from mobile station 300 and then switches to transmission. Therefore, in relay station 100, the UL reception start timing of the access link for performing communication between mobile station 300 and the own station is shifted forward by Δshift F ahead of the backhaul UL transmission end timing. Just do it. After switching from reception to transmission, the relay station 100 transmits the SRS to the base station 200.

  Therefore, SC-FDMA symbol # 13 is set as an SRS symbol in the relay station cell, but SRS transmission is not assigned to mobile station 300 connected to relay station 100. That is, in the access link subframe (access link subframe B1 in FIG. 2), SC-FDMA symbol # 13 (shaded block in FIG. 2) becomes a free symbol (Fake SRS) in which no SRS is set, and the relay station All mobile stations connected to 100 do not transmit SC-FDMA symbol # 13.

  Next, as the second transmission / reception switching timing (transmission / reception switching timing B in FIG. 2), the subframe immediately preceding the backhaul subframe A2 for performing communication between the base station 200 and the own station. When there is no SRS transmission in SC-FDMA symbol # 13, relay station 100 switches to transmission after receiving SC-FDMA symbol # 13 of access link subframe B2 from mobile station 300. Therefore, in relay station 100, the UL reception start timing of the access link for performing communication between mobile station 300 and the own station is shifted forward by Δshift F ahead of the backhaul UL transmission end timing. Just do it. After switching from reception to transmission, relay station 100 transmits SC-FDMA symbols # 0 to # 12 (in the case of normal CP length) to base station 200.

  As described above, relay station 100 according to the present embodiment switches transmission / reception switching timings A and B (see FIG. 2) for each subframe. Therefore, only in the subframe in which the relay station 100 needs to transmit the SRS in the backhaul subframe, the SRS is transmitted at the expense of the last SC-FDMA symbol of the access link, and in the subframe in which the transmission of the SRS is unnecessary. The last SC-FDMA symbol of the access link can be used for reception of PUCCH, PUSCH or SRS. Therefore, relay station 100 according to the present embodiment can improve resource utilization efficiency.

  Also, relay station 100 according to the present embodiment can transmit PUCCH and PUSCH using SC-FDMA symbols # 0 to # 12 (in the case of normal CP) at transmission / reception switching timing A and transmission / reception switching timing B. . Therefore, it is not necessary to define a new format for the backhaul subframe.

  Further, relay station 100 sets the same subframe as the subframe instructed to transmit SRS from base station 200 as the SRS of the relay station cell, and mobile station 300 under the relay station makes SC-FDMA symbol. Do not send # 13.

[Operation example of relay station 100]
Next, the transmission / reception switching operation of the relay station 100 will be described with reference to FIG. FIG. 3 is a diagram for explaining the transmission / reception switching operation of relay station 100. In the figure, the horizontal axis indicates time [μs].

  In FIG. 3, in each of frames 0, 1, and 2, subframes # 5 and # 7 (backhaul subframe) indicate communication from relay station 100 to base station 200, and the other subframes are mobile stations. Communication from 300 to the relay station 100 is shown. Each subframe includes SC-FDMA symbols # 0 to # 13. Each symbol length of the SC-FDMA symbol is approximately 71.4 [ms].

  In FIG. 3, the period between the arrows indicated by Δshift F is a guard period. The time required for the relay station 100 to switch from reception to transmission or switching from reception to transmission within the guard period is included.

  In FIG. 3, rUE transmission is the transmission timing of the mobile station 300 connected to the relay station 100 to the relay station 100, RN reception is the reception timing from the mobile station 300 at the relay station 100, and RN transmission is ENB reception indicates the transmission timing of the relay station 100 to the base station 200, and eNB reception indicates the reception timing from the relay station 100 in the base station 200.

  Also, in FIG. 3, the block indicating SC-FDMA symbols # 0 to # 13 (# is omitted, and only the numbers are shown) is inclined to indicate a symbol propagation delay.

  Here, the relay station 100 can control the reception timing of the relay station 100 from the mobile station 300 (or the transmission timing of the mobile station 300 connected to the relay station 100 to the relay station 100) indicated by RN reception. Note that the reception timing from the relay station 100 in the base station 200 (or the transmission timing of the relay station 100 to the base station 200) is set in the base station 200.

  In addition, the base station 200 sets SRS unique to the relay station 100 at intervals of 10 msec.

  Here, assuming that the “subframe for transmitting SRS” is subframe # 6, when viewed from subframe # 7 immediately after subframe # 6, SRS is transmitted in subframe # 6 immediately before. When viewed from subframe # 5, subframe # 4 immediately before is not a subframe for transmitting SRS. Therefore, as shown in FIG. 3, relay station 100 uses transmission / reception switching timing B shown in FIG. 2 in subframe # 5 in which the immediately preceding subframe # 4 is not a subframe in which SRS is transmitted. Relay station 100 uses transmission / reception switching timing A in subframe # 7, which is a subframe in which immediately preceding subframe # 6 transmits an SRS.

  As described above, relay station 100 according to the present embodiment switches transmission / reception switching timings A and B for each subframe. Therefore, the relay station 100 transmits the SRS at the expense of the last SC-FDMA symbol of the access link only in the subframe (subframe # 7 in FIG. 3) that needs to transmit the SRS in the backhaul subframe. In a subframe that does not require SRS transmission (subframe # 5 in FIG. 3), the last SC-FDMA symbol of the access link can be used for reception of PUCCH, PUSCH, or SRS. Therefore, relay station 100 according to the present embodiment can improve resource utilization efficiency.

  Next, the configuration of relay station 100 will be described with reference to FIG. FIG. 4 is a block diagram showing the configuration of relay station 100. 4 includes a wireless transmission unit 101, a data allocation unit 103, a modulation unit 105, an error correction coding unit 107, an SRS signal generation unit 109, an SRS configuration setting unit 111, and an SRS configuration. The receiving unit 113, the timing switching unit 115, the error correction decoding unit 117, the demodulation unit 119, the wireless reception unit 121, the transmission antenna 123, and the reception antenna 125 are provided. FIG. 4 illustrates a case where an uplink (Up Link UL) signal is relayed.

  Radio reception section 121 receives a signal from base station 200 via reception antenna 125, performs radio processing such as down-conversion, and outputs the result to demodulation section 119.

  Demodulation section 119 demodulates the signal input from radio reception section 121 and outputs the demodulated signal to error correction decoding section 117.

  The error correction decoding unit 117 decodes the signal input from the demodulation unit 119 and outputs the data to the error correction coding unit 107 or the SRS configuration reception unit 113. Among the decoded data, the SRS arrangement information specific to the base station cell is output to the data allocation unit 103 through the processing of the error correction coding unit 107 and the modulation unit 105. In addition, among the decoded data, relay station-specific SRS arrangement information undergoes processing in the SRS Configuration receiving unit 113, and then the data allocation unit 103, the SRS signal generation unit 109, the SRS Configuration setting unit 111, and the timing switching unit 115. Is output.

  Here, among the decoded data, the relay station 100 uses the SRS arrangement information specific to the base station cell, which is a control signal transmitted from the base station 200, and the SRS arrangement information specific to the relay station, to indicate that the relay station 100 is an SC-FDMA symbol. Recognize subframes that do not transmit # 13 and SRS subframes that are transmitted to the base station 200.

  The SRS configuration setting section 111 determines the SRS arrangement specific to the relay station cell and the SRS arrangement specific to the mobile station connected to the relay station 100, and outputs the determined information to the error correction coding section 107 and the timing switching section 115. . The SRS configuration setting section 111 determines the SRS arrangement so that the same subframe as the relay station-specific SRS arrangement designated by the base station 200 is included as the relay station cell-specific SRS arrangement.

  Error correction coding section 107 performs error correction coding on the data signal and relay station cell-specific SRS arrangement information, and outputs the result to modulation section 105.

  Modulation section 105 modulates the signal output from error correction coding section 107 and outputs the modulated signal to data allocation section 103.

  The SRS signal generation unit 109 generates an SRS signal that the relay station 100 transmits to the base station 200 based on the SRS arrangement information specific to the relay station cell received from the base station 200, and outputs the SRS signal to the data allocation unit 103.

  The data allocation unit 103 allocates the SRS signal generated by the SRS signal generation unit 109 to the resource block (RB) in the subframe in which the SRS is transmitted according to the relay station cell-specific SRS arrangement information received from the base station 200, The data is output to the transmission unit 101. Furthermore, according to the relay station cell-specific SRS arrangement information received from the base station 200, the data allocation unit 103 allocates the data of the signal modulated by the modulation unit 105 to the resource block (RB) in the subframe in which the data is transmitted. Output to the wireless transmitter.

  Here, in the present embodiment, relay station 100 does not transmit a signal to base station 200 because SC-FDMA symbol # 13 of the UL backhaul subframe is used for a guard period. However, when UL backhaul subframes are continuous, relay station 100 can transmit a signal using SC-FDMA symbol # 13 in a subframe in which switching to an access link does not occur. However, when the SRS specific to the base station is determined by the SRS arrangement information specific to the base station cell, but the SRS specific to the relay station cell is not assigned, the relay station 100 transmits a signal using SC-FDMA symbol # 13. Do not send.

  The timing switching unit 115 changes the timing of switching from reception to transmission based on the SRS arrangement specific to the relay station cell set by the base station 200 and the SRS arrangement specific to the relay station cell determined by the own station.

  Here, in a subframe in which an instruction to transmit SRS is received from base station 200, timing switching section 115 switches to transmission after receiving SC-FDMA symbol # 12 of mobile station 300. Then, the timing switching unit 115 instructs the wireless transmission unit 101 to transmit the SRS to the base station 200. In the subframe in which there is no SRS transmission instruction from the base station 200, the timing switching unit 115 switches to transmission after receiving the SC-FDMA symbol # 13 of the mobile station 300. Note that the switching timing may be changed by an instruction from the base station 200.

  Radio transmitting section 101 performs radio processing such as up-conversion on the modulated signal and transmits the signal from transmitting antenna 123 to base station 200.

(Embodiment 2)
A relay station 400 according to Embodiment 2 will be described with reference to FIGS.

  Also in the second embodiment, in a wireless relay system in which relay station 100 is replaced with relay station 400 in the wireless relay system shown in FIG. 1, a terminal (for example, mobile station 300) that cannot communicate directly with base station 200 is relay station 400. Can be communicated through.

  In the radio relay system according to the second embodiment, time division relay (TD relay) is performed as in the first embodiment. As an example, two-hop relay from the base station 200 to the relay station 400 and from the relay station 400 to the mobile station 300 can be considered, but in this embodiment, two or more hops are also applicable.

  Also, in the radio relay system according to the second embodiment, relay station 400 performs transmission from the mobile station 300 to the base station 200 to the base station 200 for each subframe, as in the first embodiment. Change the switching timing to. Then, similarly to Embodiment 1, relay station 100 determines whether or not SRS is assigned to the subframe immediately before the backhaul subframe as a reference for switching.

  Next, with reference to FIG. 5, a criterion for switching transmission / reception by relay station 400 will be described. FIG. 5 is a diagram for explaining the timing at which relay station 400 switches between transmission and reception. In the figure, the horizontal axis indicates time [μs].

  In FIG. 5, rUE transmission is the transmission timing of the mobile station 300 connected to the relay station 400 to the relay station 400, RN reception is the reception timing from the mobile station 300 at the relay station 400, and RN transmission is the base ENB reception indicates the transmission timing of the relay station 400 to the station 200, and eNB reception indicates the reception timing from the relay station 400 in the base station 200.

  Also, in FIG. 5, the block indicating SC-FDMA symbols # 0 to # 13 (# is omitted in the figure and only the numbers are shown) is inclined to indicate a symbol propagation delay. For example, in FIG. 5, the symbol transmitted from the mobile station 300 to the relay station 400 at time T5 is received by the relay station 400 at time T6.

  Here, the relay station 400 can control the reception timing of the local station from the mobile station 300 indicated by RN reception (or the transmission timing of the mobile station 300 connected to the local station to the local station). Note that the base station 200 sets the reception timing from the own station (or the transmission timing of the own station to the base station 200) in the base station 200.

  First, as a third transmission / reception switching timing (transmission / reception switching timing C in FIG. 5), relay station 400 transmits SC-FDMA symbols # 0 to # 13 of backhaul subframe A3 to base station 200 (relaying). Used when station 400 wishes to transmit PUCCH). Relay station 400 sets SRS in the cell of the local station (relay station), and uses SC-FDMA symbol # 12 of access link subframe B3 for communication between mobile station 300 and the local station as mobile station. After receiving from 300, it switches to transmission of the backhaul for performing communication between the base station 200 and the own station. For this purpose, the relay station 400 sets the UL reception start timing of the access link (access link subframes B3 and C3 in the figure) for communication between the mobile station 300 and the own station to the base station 200 and the own station. What is necessary is to shift by Δshift B backward from the UL transmission end timing of the backhaul (backhaul subframe A3 in the figure) for performing communication with the station. In the subframe set at the third transmission / reception switching timing, both PUCCH and PUSCH designed for the mobile station can be applied as they are.

  Note that SC-FDMA symbol # 13 of the access link subframe (access link subframe B3 in FIG. 5) is set as an SRS symbol in the relay station cell, but SRS is set in mobile station 300 connected to relay station 400. No transmission will be assigned. That is, in the access link subframe (access link subframe B3 in FIG. 5), SC-FDMA symbol # 13 (shaded block in FIG. 5) is a free symbol (Fake SRS) in which no SRS is set.

  Next, as a fourth transmission / reception switching timing (transmission / reception switching timing D in FIG. 5), the relay station 400 transmits an access link subframe (access link subframe in FIG. 5) to the mobile station 300 connected to the own station. This is used when SC-FDMA symbol # 13 of frame B4) is desired to be transmitted (including when it is desired to transmit SRS with SC-FDMA symbol # 13).

  Relay station 400 switches to backhaul transmission after receiving the data symbol or SRS of SC-FDMA symbol # 13 of access link subframe B4 from mobile station 300 connected to its own station. At this time, when relay station 400 transmits PUCCH, a format for PUCCH that does not use SC-FDMA symbol # 0 is required. A new format may be defined, or when the fourth transmission / reception switching timing (transmission / reception switching timing D in FIG. 5) is used without defining the format, the information to be transmitted to the PUCCH is always set to PUSCH. It is also possible to use a rule of multiplexing.

  Since relay station 400 according to Embodiment 2 uses both the third and fourth transmission / reception switching timings, it switches between the third transmission / reception switching timing and the fourth transmission / reception switching timing for each subframe. By switching between these two transmission / reception switching timings, the relay station 400 can (1) always transmit the SC-FDMA symbol # 0 that cannot be transmitted when using only the third transmission / reception switching timing. Furthermore, (2) when only the fourth transmission / reception switching timing is used, the movement connected to the own station without the interval between the setting of the backhaul subframe and the setting of the SRS of the mobile station under the relay station Although the station is transmitting SRS, it is possible to prevent the local station from ignoring the SRS of the mobile station and switching to transmission.

  Next, with reference to FIGS. 6 and 7, the switching timing setting methods (1) and (2) will be described with respect to the switching of the third and fourth transmission / reception switching timings described above.

<Setting method (1)>
In setting method 1, relay station 400 determines whether to use one of the third transmission / reception switching timing and the fourth transmission / reception switching timing for each subframe, and uses the determination result as base station 200. To notify.

  The relay station 400 determines the position of the backhaul subframe instructed from the base station 200, the number of mobile stations under its own station (relay station), and the channel quality between the own station (relay station) and the mobile station. Depending on the status, a subframe for transmitting SRS to a mobile station under its own station (relay station) is determined. Then, the relay station 400 sets the timing D when the SRS transmission of the mobile station under its own station (relay station) and the subframe immediately before the backhaul subframe collide with each other, and sets the other timing as the timing C. Then, the base station 200 is notified. Relay station 400 is instructed in advance by base station 200 regarding the position of the backhaul subframe described above.

  Here, with reference to FIG. 6, the configuration of relay station 400 for setting setting method (1) will be described. FIG. 6 is a block diagram showing a configuration of relay station 400. The configuration of relay station 400 shown in FIG. 6 is different from the configuration of relay station 100 shown in FIG. 4 in timing switching instruction generation unit 401 and timing switching unit 415. Detailed description of the common configuration is omitted.

  The timing switching instruction generation unit 401 includes SRS arrangement information specific to the own station (relay station), SRS arrangement information specific to the own station (relay station) cell, and the own station (relay station), determined by the SRS configuration setting unit 111. Timing switching instruction information is generated from the SRS arrangement information unique to the mobile station connected to. Then, the generated timing switching instruction information is output to error correction encoding section 107 and timing switching section 415.

  The timing switching unit 415 switches the third transmission / reception switching timing and the fourth transmission / reception switching timing described above based on the timing switching instruction information.

  Note that the third transmission / reception switching timing may be used in the subframe in which the relay station 400 transmits the PUCCH to the base station 200, and the fourth transmission / reception switching timing may be used in the subframe in which the PUCCH is not transmitted.

<Setting method (2)>
Here, with reference to FIG. 7, a configuration of relay station 400A for setting setting method (2) will be described as a modification of relay station 400. In the setting method (2), the base station 200 notifies the relay station 400A of which transmission / reception switching timing of the third transmission / reception switching timing or the fourth transmission / reception switching timing is used for each subframe. Then, the relay station 400A is configured so that the subframe serving as the third transmission / reception switching timing does not overlap the SRS transmission subframe that transmits the SRS of the mobile station connected to the local station (relay station). The SRS transmission subframe of the mobile station 300 and the interval between the subframes are set.

  FIG. 7 is a block diagram showing a configuration of relay station 400A. Note that the configuration of relay station 400A shown in FIG. 7 is different from the configuration of relay station 100 shown in FIG. 4 in timing switching instruction receiving unit 403 and timing switching unit 415A. Detailed description of the common configuration is omitted.

  Timing switching instruction receiving section 403 receives timing switching information transmitted from base station 200, and outputs the information to timing switching section 415A.

  The timing switching unit 415A switches between the third transmission / reception switching timing and the fourth transmission / reception switching timing as instructed from the base station.

(Embodiment 3)
Next, relay station 700 according to Embodiment 3 will be described with reference to FIGS.

  Also in Embodiment 3, in a wireless relay system in which relay station 100 is replaced by relay station 700 in the wireless relay system shown in FIG. Can be communicated through.

  In the wireless relay system according to the third embodiment, time division relay (TD relay) is performed as in the first embodiment. As an example, two-hop relay from the base station 200 to the relay station 700 and from the relay station 700 to the mobile station 300 can be considered, but in the present embodiment, even two hops or more are applicable.

  The relay station 700 according to the present embodiment uses the third transmission / reception switching timing (transmission / reception switching timing C in FIG. 8) and the new fifth transmission / reception switching timing (transmission / reception switching timing E in FIG. 8) Switch every frame.

  Next, the two transmission / reception switching timings described above in relay station 700 according to the present embodiment will be described with reference to FIG. FIG. 8 is a diagram for explaining the timing at which relay station 700 switches between transmission and reception.

  In FIG. 8, rUE transmission is the transmission timing of mobile station 300 connected to relay station 700 to relay station 700, RN reception is the reception timing from mobile station 300 at relay station 700, and RN transmission is base station The eNB reception indicates the transmission timing of the relay station 700 to the station 200, and the reception timing from the relay station 700 in the base station 200.

  In FIG. 8, a period between the arrows indicated by Δshift F is a guard period. In addition, the switching period in the figure is a time required for the relay station 700 to switch from transmission to reception or from reception to transmission.

  Also, in FIG. 8, the block indicating SC-FDMA symbols # 0 to # 13 (# is omitted, and only the numbers are shown) is inclined, indicating a symbol propagation delay. For example, in FIG. 8, a symbol transmitted from mobile station 300 to relay station 700 at time T7 is received by relay station 700 at time T8.

  Here, relay station 700 can control the reception timing of relay station 700 from mobile station 300 indicated by RN reception (or the transmission timing of mobile station 300 connected to relay station 700 to relay station 700). Note that the reception timing from the relay station 700 in the base station 200 (or the transmission timing of the relay station 700 to the base station 200) is set in the base station 200.

  Further, the base station 200 sets SRS unique to the relay station 700 at intervals of 10 msec.

  First, as a third transmission / reception switching timing (transmission / reception switching timing C in FIG. 8), relay station 700 transmits SC-FDMA symbols # 0 to # 13 of backhaul subframe A5 to base station 200 (relaying). Used when station 700 wants to transmit PUCCH). Relay station 700 sets SRS in the cell of the local station (relay station), and uses SC-FDMA symbol # 12 of access link subframe B5 for communication between mobile station 300 and the local station as mobile station. After receiving from 300, it switches to transmission of the backhaul for performing communication between the base station 200 and the own station. Therefore, in relay station 700, the UL reception start timing of the access link (access link subframes B5 and C5 in FIG. 8) for performing communication between mobile station 300 and its own station is set to that of base station 200. The backhaul (Backhaul) for performing communication with the own station (backhaul subframe A5 in FIG. 8) may be shifted backward by Δshift B from the UL transmission end timing. In the subframe set at the third transmission / reception switching timing, both PUCCH and PUSCH designed for the mobile station can be applied as they are.

  Note that the access link subframe (access link subframe B5 in FIG. 8) SC-FDMA symbol # 13 is set as an SRS symbol in the relay station cell, but SRS transmission is performed for the mobile station 300 connected to the relay station 700. It will not be assigned. That is, in the access link subframe (access link subframe B5 in FIG. 8), SC-FDMA symbol # 13 (shaded block in FIG. 8) is a free symbol (Fake SRS) in which no SRS is set.

  Next, the fifth transmission / reception switching timing (transmission / reception switching timing E in FIG. 8) will be described. The fifth transmission / reception switching timing is different from the above-described third transmission / reception switching timing in the timing of switching from the backhaul subframe to the access link subframe, that is, the switching timing from transmission to reception.

  At the fifth transmission / reception switching timing, relay station 700 transmits SC-FDMA symbol # 12 of backhaul subframe A6 and then switches to reception. In access link subframe C6, relay station 700 has the same subframe number as that of backhaul subframe A6. SC-FDMA symbol # 13 is received, and the SC-FDMA symbol is received as it is in the access link subframe C6 of the next subframe.

  As described above, relay station 700 according to the present embodiment has third transmission / reception switching timing (transmission / reception switching timing C in FIG. 8) and fifth transmission / reception switching timing (transmission / reception switching timing E in FIG. 8). Is switched. Therefore, when the SRS arrangement specific to the base station cell is set in the backhaul subframe and the SRS arrangement specific to the relay station is not set, the relay station 700 does not need to transmit the SC-FDMA symbol # 13. That is, in the backhaul subframe (backhaul subframe A6 in FIG. 8), SC-FDMA symbol # 13 becomes an empty symbol (Fake SRS). Therefore, the SC-FDMA symbol # 13 of the access link subframe C6 can be received, and the relay station 700 has the access link subframe (in the figure, the access link subframe C6 in the SRS arrangement unique to the mobile station under the relay station). ) SC-FDMA symbol # 13.

  As described above, relay station 700 according to the present embodiment cannot receive SRS from mobile station 300 in the subframe before the backhaul, but receives SRS of mobile station 300 in the same subframe as the backhaul. can do.

  Also, relay station 700 according to the present embodiment can transmit SRS and data to base station 200 using SC-FDMA symbol # 13 at the above-described third transmission / reception switching timing. Therefore, relay station 700 according to the present embodiment can set subframes for adaptively transmitting SRS by switching timing.

  Further, relay station 700 according to the present embodiment does not cause SC-FDMA symbol # 0 to be transmitted in the switching between the third transmission / reception switching timing and the fifth transmission / reception switching timing described above, and PUCCH It can be operated without setting a new format.

[Operation example of relay station 700]
Next, the transmission / reception switching operation of the relay station 700 will be described with reference to FIG. FIG. 9 is a diagram for explaining the transmission / reception switching operation of relay station 700. In the figure, the horizontal axis indicates time [μs].

  In FIG. 9, in frame 1, in subframe # 4, relay station cell-specific SRS arrangement and no mobile station-specific SRS are assigned. Further, in subframe # 5, the base station cell-specific SRS arrangement and the relay station-specific SRS are not assigned. In addition, mobile station specific SRS connected to relay station 700 is assigned to subframe # 6.

  In FIG. 9, in frame 1, subframes # 5 and # 7 (backhaul subframes) indicate communication from relay station 700 to base station 200, and other subframes are transmitted from the mobile station to the relay station. Communication (access link subframe) is shown. Each subframe includes SC-FDMA symbols # 0 to # 13. Each symbol length of the SC-FDMA symbol is approximately 71.4 [ms].

  In FIG. 9, rUE transmission is the transmission timing of the mobile station 300 connected to the relay station 700 to the relay station 100, RN reception is the reception timing of the relay station 700 from the mobile station 300, and RN transmission is ENB reception indicates the transmission timing of the relay station 700 to the base station 200, and eNB reception indicates the reception timing from the relay station 700 in the base station 200.

  In FIG. 9, the blocks indicating SC-FDMA symbols # 0 to # 13 are inclined to indicate symbol propagation delay.

  Here, relay station 700 can control the reception timing of relay station 700 from mobile station 300 indicated by RN reception (or the transmission timing of mobile station 300 connected to relay station 700 to relay station 700). Note that the reception timing from the relay station 700 in the base station 200 (or the transmission timing of the relay station 700 to the base station 200) is set in the base station 200.

  Further, the base station 200 sets SRS unique to the relay station 700 at intervals of 10 msec.

  When the relay station 700 switches from the backhaul subframe to the access link subframe, the base station cell-specific SRS arrangement and the relay station-specific SRS are not allocated in the backhaul subframe. Switching timing (transmission / reception switching timing E in FIG. 8) is used. That is, in FIG. 9, in subframe # 5, which is a backhaul subframe, since the base station cell-specific SRS arrangement and the relay station-specific SRS are not assigned, the relay station 700 performs the fifth transmission / reception switching timing described above. (Transmission / reception switching timing E in FIG. 8) is used to switch from the backhaul subframe to subframe # 6, which is an access link subframe.

  Also, as the third transmission / reception switching timing (transmission / reception switching timing C in FIG. 9), when relay station 700 transmits SC-FDMA symbols # 0 to # 13 to base station 200 (relay station 700 transmits PUCCH). (Including when you want to). Relay 700 sets SRS in the cell of its own station (relay station), receives SC-FDMA symbol # 12 from mobile station 300, and then switches to backhaul transmission.

  However, the relay station 700 uses the third transmission / reception switching timing instead of the fifth transmission / reception switching timing when the SRS specific to the mobile station under the relay station is not assigned to the same subframe as the backhaul subframe. May be.

  Relay station 700 uses the third transmission / reception switching timing described above when the base station cell-specific SRS arrangement is not used or when the base station cell-specific SRS arrangement is assigned but the relay station-specific SRS is assigned. .

  Next, the configuration of relay station 700 will be described with reference to FIG. FIG. 10 is a block diagram showing the configuration of relay station 700. The relay station 700 shown in FIG. 10 is different from the relay station 100 shown in FIG. 4 in a data allocation unit 703, an SRS configuration setting unit 711, and a timing switching unit 715. The same reference numerals are assigned to the common components, and detailed description thereof is omitted.

  The SRS configuration setting unit 711 determines the location of the relay station cell-specific SRS and the location of each UE-specific SRS connected to the own station (relay station), and determines the determined information as the error correction encoding unit 107, timing switching Output to the unit 715.

  Here, when switching from the backhaul subframe to the access link subframe, the base station cell-specific SRS arrangement and the relay station-specific SRS are not allocated in the backhaul subframe (subframe # 5 in FIG. 9). In this case, the relay station 700 can assign the SRS specific to the mobile station cell under the relay station to the same subframe as the backhaul subframe.

  Data allocation section 703 allocates an SRS signal to a resource block (RB) in a subframe in which SRS is transmitted according to relay station-specific SRS arrangement information received from base station 200, and data in a subframe in which data is transmitted in a resource block Assign to (RB) and output to the wireless transmission unit 101.

  The timing switching unit 715 changes the timing of switching from reception to transmission based on the relay station-specific SRS arrangement determined by the base station 200 and the relay station cell-specific SRS arrangement set by the relay station.

  That is, the timing switching unit 715 switches to reception after transmitting SC-FDMA symbol # 13 in the backhaul subframe in which the SRS transmission instruction is received from the base station 200. In addition, the timing switching unit 715 is assigned to the base station cell-specific SRS arrangement, but in the backhaul subframe to which the relay station-specific SRS is not assigned, the SC-FDMA symbol # 12 is transmitted and then received. Switch.

  In each of the above embodiments, the TD relay is also referred to as a half duplex relay. In addition, among In band relays, when there is not sufficient isolation between the transmitting antenna and the receiving antenna, these Relays are used.

  In each of the above embodiments, the normal CP subframe has been described as an example. However, in the case of an extended CP (one symbol length is long and one frame is composed of 12 SC-FDMA symbols), SC-FDMA in which SRS is transmitted. The symbol number is # 11 (starting from # 0). In the case of the extended CP only on the access link side, in the case of the extended CP only on the backhaul side, both may be extended CPs.

  In each of the above-described embodiments, when UL backhaul subframes are continuously allocated, switching between the head subframe of the continuous subframe and the subframe of the access link immediately before that subframe is performed. The above embodiments are applied.

  In each of the above embodiments, the transmission antenna or the reception antenna has been described. However, the present invention can be similarly applied to an antenna port. An antenna port refers to a logical antenna composed of one or a plurality of physical antennas. That is, the antenna port does not necessarily indicate one physical antenna, but may indicate an array antenna composed of a plurality of antennas. For example, in LTE, it is not defined how many physical antennas an antenna port is composed of, but is defined as a minimum unit in which a base station can transmit different reference signals. The antenna port may be defined as a minimum unit for multiplying the weight of the precoding vector.

  Each functional block used in the description of each of the above embodiments is typically realized as an LSI which is an integrated circuit. These may be individually made into one chip, or may be made into one chip so as to include a part or all of them. The name used here is LSI, but it may also be called IC, system LSI, super LSI, or ultra LSI depending on the degree of integration.

  Further, the method of circuit integration is not limited to LSI's, and implementation using dedicated circuitry or general purpose processors is also possible. An FPGA (Field Programmable Gate Array) that can be programmed after manufacturing the LSI or a reconfigurable processor that can reconfigure the connection and setting of circuit cells inside the LSI may be used.

  Further, if integrated circuit technology comes out to replace LSI's as a result of the advancement of semiconductor technology or a derivative other technology, it is naturally also possible to carry out function block integration using this technology. Biotechnology can be applied.

  Although the present invention has been described in detail and with reference to specific embodiments, it will be apparent to those skilled in the art that various changes and modifications can be made without departing from the spirit and scope of the invention.

  This application is based on a Japanese patent application (Japanese Patent Application No. 2010-029408) filed on Feb. 12, 2010, the contents of which are incorporated herein by reference.

  The radio relay apparatus or radio relay method according to the present invention has an effect of improving the resource utilization efficiency, and is useful as a radio relay station apparatus or the like.

100, 400, 400A, 700 Relay station 101 Wireless transmission unit 103, 703 Data allocation unit 105 Modulation unit 107 Error correction coding unit 109 SRS signal generation unit 111, 711 SRS configuration setting unit 113 SRS configuration reception unit 115, 415, 415A , 715 Timing switching unit 117 Error correction decoding unit 119 Demodulation unit 121 Radio reception unit 123 Transmission antenna 125 Reception antenna 200 Base station 300 Mobile station 401 Timing switching instruction generation unit 403 Timing switching instruction reception unit

Also in Embodiment 3, in a wireless relay system in which relay station 100 is replaced with relay station 700 in the wireless relay system shown in FIG. 1, a terminal (for example, mobile station 300) that cannot communicate directly with base station 200 is relay station 700. Can be communicated through.

In FIG. 9, rUE transmission is the transmission timing of the mobile station 300 connected to the relay station 700 to the relay station 700 , RN reception is the reception timing from the mobile station 300 at the relay station 700, and RN transmission is ENB reception indicates the transmission timing of the relay station 700 to the base station 200, and eNB reception indicates the reception timing from the relay station 700 in the base station 200.

Claims (7)

A wireless relay device for relaying a signal between a base station and a mobile station,
Using a backhaul subframe that is a subframe for performing communication between the base station and the own device, a transmission unit that transmits a signal and SRS toward the base station;
Using the access link subframe, which is a subframe for communication between the mobile station and its own device, the reception start of the access link subframe shifted before the transmission end timing of the backhaul subframe At a timing, a receiving unit that receives a signal and SRS transmitted toward the device,
A switching unit that switches between a transmission mode for performing transmission from the own device to the base station and a reception mode for performing reception from the mobile station;
An SRS setting unit that sets an arrangement of SRS that the mobile station transmits toward the own device, and
When the transmission unit transmits the SRS in a subframe immediately before the backhaul subframe, the SRS setting unit directs the final symbol of the access link subframe to the mobile station. Set SRS to be transmitted as an empty symbol that is not placed,
After the receiving unit has received a signal transmitted from the mobile station to the own device with a symbol immediately before the empty symbol, the switching unit switches from the reception mode to the transmission mode,
When the transmission unit does not transmit the SRS in the subframe immediately before the backhaul subframe, the reception unit is directed to the mobile station from the mobile station with the last symbol of the access link subframe. After receiving the transmitted signal, the switching unit switches from the reception mode to the transmission mode,
A wireless relay device characterized by that. A wireless relay device for relaying a signal between a base station and a mobile station,
Using a backhaul subframe that is a subframe for performing communication between the base station and the own device, a transmission unit that transmits a signal and SRS toward the base station;
Reception start timing of the access link subframe shifted after the transmission end timing of the backhaul subframe using an access link subframe which is a subframe for performing communication between the mobile station and the own device And a receiving unit for receiving the signal and SRS transmitted toward the device,
A switching unit that switches between a transmission mode for performing transmission from the own device to the base station and a reception mode for performing reception from the mobile station;
An SRS setting unit that sets an arrangement of SRS that the mobile station transmits toward the own device, and
When the transmission unit transmits the signal using the first symbol of the backhaul subframe, the SRS setting unit transmits the last symbol of the access link subframe, and the SRS that the mobile station transmits to the mobile station. Set it as an empty symbol that is not placed,
After the receiving unit has received a signal transmitted from the mobile station to the own device with a symbol immediately before the empty symbol, the switching unit switches from the reception mode to the transmission mode,
When the transmitter does not transmit the signal using the first symbol of the access link subframe, the receiver transmits the signal transmitted from the mobile station to the own device using the last symbol of the access link subframe. The switching unit switches from the reception mode to the transmission mode,
A wireless relay device characterized by that. A wireless relay device for relaying a signal between a base station and a mobile station,
Using a backhaul subframe that is a subframe for performing communication between the base station and the own device, a transmission unit that transmits a signal and SRS toward the base station;
Reception start timing of the access link subframe shifted after the transmission end timing of the backhaul subframe using an access link subframe which is a subframe for performing communication between the mobile station and the own device And a receiving unit for receiving the signal and SRS transmitted toward the device,
A switching unit that switches between a transmission mode for performing transmission from the own device to the base station and a reception mode for performing reception from the mobile station;
An SRS setting unit that sets an arrangement of SRS that the mobile station transmits toward the own device, and
When the transmission unit transmits the signal with the final symbol of the backhaul subframe, the transmission unit transmits the signal with the final symbol of the backhaul subframe. Switch to the reception mode from
When the transmitter does not transmit the signal with the final symbol of the backhaul subframe, the SRS setting unit transmits the SRS that the device itself transmits to the base station, with the final symbol of the backhaul subframe. Set it as an empty symbol that is not placed,
After the transmission unit has transmitted the signal with a symbol one prior to the final symbol, the switching unit switches from the transmission mode to the reception mode,
After the switching unit switches from the transmission mode to the reception mode, the receiving unit receives the last symbol of the access link subframe having the same subframe number as that of the backhaul subframe from the mobile station. Receive signals sent to
A wireless relay device characterized by that. The SRS setting unit
As a subframe in which the base station or the device itself may receive SRS, cell-specific SRS arrangement is determined for each cell,
The radio according to claim 1 or 2, wherein the empty symbol is set by determining an SRS arrangement specific to a mobile station from subframes included in the determined cell-specific SRS arrangement. Relay device. A wireless relay method for relaying a signal between a base station and a mobile station,
At the reception start timing of the access link subframe shifted before the transmission end timing of the backhaul subframe, the signal and SRS transmitted to the relay station are received,
When SRS is transmitted in a subframe immediately before the backhaul subframe,
The final symbol of the access link subframe is set as an empty symbol that does not place an SRS that the mobile station transmits to the relay station,
After receiving a signal transmitted from the mobile station to the relay station at a symbol immediately preceding the empty symbol, switching to transmission from the relay station to the base station, and
When the SRS is not transmitted in the subframe immediately before the backhaul subframe,
In the final symbol of the access link subframe, after receiving a signal transmitted by the mobile station toward the relay station, the transmission is switched from the relay station to the base station.
And a wireless relay method. A wireless relay method for relaying a signal between a base station and a mobile station,
At the reception start timing of the access link subframe shifted after the transmission end timing of the backhaul subframe, the signal and SRS transmitted toward the relay station are received,
When a signal is transmitted in the first symbol of the backhaul subframe,
The final symbol of the access link subframe is set as an empty symbol in which no SRS is transmitted from the mobile station to the relay station, and the mobile station sends the relay station one symbol before the empty symbol. After receiving a signal transmitted to the base station, switching from the relay station to the base station, and
If the signal is not transmitted in the first symbol of the backhaul subframe,
In the final symbol of the access link subframe, after receiving a signal transmitted from the mobile station to the relay station, switch to transmission from the relay station to the base station,
And a wireless relay method. A wireless relay method for relaying a signal between a base station and a mobile station,
At the reception start timing of the access link subframe shifted after the transmission end timing of the backhaul subframe, the signal and SRS transmitted toward the relay station are received,
When a signal is transmitted in the last symbol of the backhaul subframe,
After the signal is transmitted in the last symbol of the backhaul subframe, switching to reception from the mobile station to the relay station, and
If the signal is not transmitted in the last symbol of the backhaul subframe,
The final symbol of the backhaul subframe is set as an empty symbol in which no SRS is transmitted to the base station by the relay station, and after transmitting the signal with a symbol immediately before the final symbol, Switch to reception from the mobile station to the relay station, and receive a signal transmitted from the mobile station to the relay station in the last symbol of the access link subframe having the same subframe number as the backhaul subframe. To
And a wireless relay method.

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